Secure optical information disc having a minimized metal layer

ABSTRACT

A secure optical data disc comprising an electronic article surveillance tag embedded within a layered disc structure comprising first and second substrates is disclosed. The tag is placed within a non-readable zone (i.e., one that does not have data tracks) of the secure disc. To improve signal quality of the tag, the reflective metal layer thickness is minimized and discontinuities are introduced on the reflective metal layer. A first discontinuity separates a data track region of the disc from a mirror/ID band region. A second, radial discontinuity opens the mirror/ID band ring.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the priority benefit of Bigley, U.S. Provisional Patent Application Ser. No. 60/455,284, filed on Mar. 17, 2003, and Bigley, U.S. patent application Ser. No. 10/792,352, filed on Mar. 3, 2004, entitled “Secure Optical Information Disc,” the contents of both referenced patent applications are incorporated herein by reference in their entirety, including any references therein.

TECHNICAL FIELD

This invention generally relates to electronic data storage media such as those used to store music, movies, software (including games), and other valuable electronic data assets distributed through retail and/or rental outlets. More particularly, the invention relates to the manufacture of optical data storage discs for carrying an electronically detectable security tag. The security tag potentially embodies a variety of electronic article surveillance (EAS) technologies including ones that generate specific identification codes for inventory control (e.g., RFID and smart tags) as well as ones that, unless deactivated, resonate at a particular frequency (or range) and activate an alarm when passed through an electronic surveillance gate.

BACKGROUND

Optical data storage discs are the predominant media for storing music, movies and software (including general PC software as well as video game software played upon game consoles connected to televisions/monitors) distributed via retail outlets. Today, music is encoded on an optical data storage disc using compact disc (CD) technology. Software that is distributed through retail outlets is also typically stored on optical data storage discs embodying the CD technology. Movies and games (executed on game consoles) are encoded on optical data storage discs using digital versatile disc (DVD) technology that holds significantly more data than a CD.

Retail theft of optical data storage discs storing valuable digital data assets has received considerable attention from retailers. Initially, theft was deterred through the use of bulky, six by 12 inch cardboard boxes that were difficult for shoplifters to conceal. Later, equally bulky, plastic frames were placed around the boxes to deter theft. While such packaging was an effective deterrent, it created substantial solid waste. Thus, the bulky boxes were abandoned and today, CDs are generally packaged in the well-known “jewel” case. Similarly, DVDs for movies are generally displayed for retail customers within slightly larger plastic cases including one or more optical data storage discs. On the other hand, retailers have resorted to placing DVDs containing game console software in locked cabinets to deter theft.

In the 1990s electronic security mechanisms replaced bulky packaging as a means for discouraging/controlling retail theft. In particular, electronic surveillance tags are now placed on/within optical disc storage retail packaging. Unless deactivated at the checkout counter, the security tags are sensed by surveillance panels positioned at the entrance/exit of a retail establishment. If not deactivated, sensors within the panels detect the security tag when a person attempts to leave with the case containing the security tag and an alarm is activated. A number of such security tag technologies are well known in the art.

Currently electronic security tags are attached to a case within which a DVD, for a movie or game, is held. If the case is taken from a retail establishment before the security tag is deactivated, then an alarm sounds when the security tag passes through security panels at the door. A shortcoming of attaching security tags to a package/case containing an optical disc is that a shoplifter need only remove the disc from the package (or remove the security tag from the package) to evade detection by security panels placed at a store's exit. As a consequence, retailers continue to maintain their game software within locked cases. Alternatively, and apparently to address the shortcomings of attaching a security tag to a CD case, attaching a security tag to a CD disc having a single substrate has been proposed a number of times in the prior art. These previous proposed CD structures have yet to be adopted commercially by retailers. Introducing a security tag introduces the possibility that the security tag will interfere with playing the disc by a purchaser of the disc. One problem arising from attaching a security device directly to a disc is the need to maintain balance. Another restriction is that incorporating a security tag onto the disc itself should not cause the disc to no longer meet specified space/dimension standards for the particular optical data storage media.

Yet another potential challenge of incorporating a security tag into storage media is providing a sufficiently strong signal, by the security tag, for sensing by a security gate. The security tag must fit within a relatively small space. However, the reduced size inevitably leads to the security tag transmitting a weaker signal.

SUMMARY OF THE INVENTION

The present invention is directed to a secure disc arrangement and method for manufacturing the secure disc such that a resulting optical disc is produced in a manner: conforming to the space limitations of the optical disc media standards organizations, providing a sufficiently strong signal to ensure detection of a security tag embedded in the hub of the optical disc media, and meeting the production throughput/timing requirements of manufacturers—thereby providing both a technological as well as commercially acceptable solution to a need to control theft of movies, programs and games stored upon optically encoded media (e.g., DVDs) comprising a metalized layer that potentially interferes with sensing a signal generated by the security tag.

The present invention thus comprises a secure optical data storage disc. The secure disc includes a first substrate. The substrate, by way of example, is formed by injecting molten plastic within a mold. The secure disc has a non-readable zone that does not include data tracks (disposed upon a readable surface of the disc). The security tag is disposed within the non-readable zone of the disc and thus does not interfere with reading the data tracks. The metalized layer thickness is substantially reduced in comparison to previously manufactured discs. Reducing and minimizing the metalized layer thickness reduces its shielding effect upon signals generated by the security tag that are sensed by a security gate at a retail establishment.

Furthermore, in accordance with more particular embodiments of the invention where a metalized ID band is present (as opposed to a semiconductor or non-conductive ID band), discontinuities are introduced within metalized areas of the secure disc to reduce interference/shielding of the signals generated by security tags. First, a disruption is introduced between an outer portion of the disc containing the optically sensed digital data tracks and an inner portion comprising the ID band (also referred to as the “mirror” band). Also, a radial disruption is introduced in the ID band itself to further improve the ability of a security gate to sense the signal generated by the security tag. The aforementioned gaps need not be introduced in the case where the mirror band is made up of semiconductor (e.g., silicon) or non-conductor materials.

The format and layering of the data tracks differs in accordance with various embodiments of the invention.

The present invention is intended to encompass a variety of optically encoded discs carrying a variety of information assets within a reflective/semi-transmissive layer carried on one or more substrates. The invention is embodied, for example, within DVDs that are encoded with movies, videogame console game software, and software in general. Such embedding prevents separation of a disc from its EAS tag and as such provides a significantly higher barrier to circumvention, by would-be shoplifters, than other known arrangements that merely embed the tag within a case. The present invention is intended to be carried out through the use of a variety of thin film EAS technologies arranged in a variety of topologies and circuits. The invention will be described, by way of illustrative examples, further herein below.

BRIEF DESCRIPTION OF THE DRAWINGS

While the appended claims set forth the features of the present invention with particularity, the invention, together with its objects and advantages, may be best understood from the following detailed description taken in conjunction with the accompanying drawings of which:

FIG. 1 is a schematic plan view of an exemplary secure disc comprising an annular security tag sandwiched between two substrates of an optical disc and located within the non-data region of disc;

FIGS. 2 a-2 c are cross-sectional views of various types of secure DVD disc formats;

FIGS. 3 a-d are a set of plan views of various security tag coil configurations;

FIGS. 4 a-4 b are DVD layer summaries for an initial molding stage for DVD-14 and DVD-18 formats;

FIGS. 5 a-5 b are DVD layer summaries for an intermediate (stripped) stage for DVD-14 and DVD-18 formats;

FIGS. 6 a-6 b are DVD layer summaries for a final assembly stage for DVD-14 and DVD-18 formats;

FIG. 7 is a plan view of an assembly line for carrying out DVD manufacturing in accordance with an embodiment of the present invention;

FIGS. 8 a-8 b summarizes exemplary fabrication stages for DVD-5 and DVD-9 discs comprising security tags embedded between two substrates; and

FIGS. 9 a-9 b illustratively depict (by comparison to a prior art disc) additional features of a minimized metal disk that enhances sensing a signal generated by the security tag embedded within a secure disc in accordance with embodiments of the present invention.

DETAILED DESCRIPTION OF THE DRAWINGS

A secure disc, including all formats (e.g., CD, DVD, etc.), comprises, by way of example and not limitation, a security tag sandwiched between first and second substrates of the secure disc (or alternatively placed within an recess on a single substrate and covered by a lacquer layer). At least an antenna portion of the security tag occupies a region of the disc that is not encoded with optically sensed data. The location of the security tag avoids interfering with optically sensed data stored upon the secure disc. In exemplary embodiments, the security tag is sandwiched between first and second substrates at a location near the hub of the secure disc (e.g., within a clamping region, and potentially extending into a mirror band area).

Furthermore, the security tag is substantially balanced with regard to a rotational axis of the secure disc. In an embodiment of the invention the security tag is ring-shaped (i.e., defined by concentric circular inner and outer edges). Thus, when concentrically embedded/sandwiched between two substrates of the secure disc, the thin film security tag neither unbalances the disc nor interferes with data acquisition from the disc.

The present invention contemplates a variety of thin film EAS sensor technologies/topologies. In particular embodiments of the invention, the security tag is provided in the form of an insulated thin film resonating device including capacitively coupled coiled circuits, carried by an insulating thin film, constituting an inductor/capacitor (LC), or resonant, circuit. The insulating thin film establishes the capacitive aspect of the LC circuit by slightly offsetting pairs of metallic coils that make up the security tag. The paired coils of the security tag have sufficient surface area to resonate when exposed to electromagnetic energy at a frequency within a particular frequency range. Alternatively, a separate capacitor circuit, separate from the metallic coils, provides at least a portion of the capacitive aspect of the security tag.

The signal generated by the security tag sandwiched between the two substrates of an optical data storage disc is detected by a receiving antenna thereby making it a viable electronic article surveillance anti-theft device capable of discouraging theft of the optical data storage disc. Additional features reduce the interference/shielding effect of the metalized layer of the optical data storage disc on a signal generated by the coil of the security tag. Such features include the metalized reflective data layer (to produce a minimized metal disc) having a substantially reduced thickness. Yet another signal-improving feature includes a first (e.g., concentric) discontinuity introduced between the ID band and the digital data tracks on a reflective metal layer of the disc. Still another source for improved security tag signal transmission comprises a radial discontinuity introduced in the ID band itself.

Turning to the drawings, and in particular FIG. 1, the invention is presented in the form of a secure optical data storage disc 100 (also referred to herein as “secure disc 100”) that comprises a security tag 102 sandwiched/embedded between a first and second substrate. In general, the tag occupies a non-readable surface area on the disc 100. In the illustrative embodiment, based upon DVD standard dimensions, the security tag 102 comprises a thin film LC resonating device that resides, by way of example, primarily within an annular clamping area 106 of the secure disc 100 (and centered with regard to the axis of rotation of the disc 100). The clamping area 106 is defined by a ring with an inner diameter of 22.0 mm and an outer radius of 33.0 mm.

The size/dimensions of the security tag 102 are generally bound by the requirement that it does not interfere with reading encoded data—and should not be shielded by a metal layer, and therefore at least the antenna portion of the security tag 102 occupies non-readable regions of the secure disc 100. Thus, in embodiments of the invention, at least a portion of the security tag 102 extends beyond the clamping area 106 to other regions of the disc 100. For example, in an embodiment of the invention the security tag extends into an annular portion 108 of the secure disc 100 having an inner diameter of 15.0 mm and outer diameter of 22.0 mm. However, the tag 102 does not extend over the rim of the center hole (at a radial distance of 15.0 mm. from the rotational axis of the disc 100). In this embodiment the security tag 102 occupies an area from 15.0 mm to 36.0 mm (just outside a stacking ring 110, if present, at a diameter of 33.5 mm) thereby enhancing the signal strength of the security tag.

Furthermore, to provide a stronger signal, in alternative embodiments of the invention, the outer edge of the surface area of the security tag 102 is potentially extended into a non-readable region beyond the stacking ring 110 diameter (33.5 mm)—a concentric ring having an inner diameter of 38.0 mm. and outer diameter of 44.0 mm. (see, FIG. 9 b). This region is referred to as the mirror/ID band region of the disc. On the other hand, in such alternative embodiments of the invention, the security tag 102 does not extend beyond the mirror-band region into a readable region 112 of the secure disc 100 so as to obscure readable data tracks that begin at a diameter of 45.0 mm and end at a diameter of 118 mm in the illustrative embodiment since the coil/antenna is not to be shielded by a metal layer. However, in embodiments of the invention, certain non-radiating circuit components of the security tag 102, such as a capacitor or diode, may be hidden under the mirror band, to fully utilize available space to maximize the signal strength of the resonator.

The mirror band region contains information that is visually or electronically scanned to provide information. In the case of a DVD with two content-laden substrates, two barcodes are provided. The barcodes are offset so that a barcode reader can access both barcodes from one side of the disc. The mirror band is isolated from the portion of the metal layer constituting the data portion of the disc through double masking—i.e., a first mask is used to sputter the data tracks, and a second mask is used to sputter the mirror band such that a concentric (ring) disruption is introduced between the metalized data track region and the metalized mirror band that layer-wise fall within a same layer of an optically sensed disc. The second sputtering step deposits a layer of metal for the mirror band that is thicker than the metal layer for the data tracks.

As will be evident to those skilled in the art, the above-described exemplary embodiment can be modified in a number of ways, including, without limitation modifying: any of the identified dimensions (including the disc itself), the size of the security tag 102, the type of encoding of data on the disc (e.g., CD, DVD, etc.), the type of information encoded/embodied in the security tag (e.g., an RFID tag providing a value corresponding to the particular disc—as opposed to merely resonating at a particular frequency to which a sensor is tuned), and the type of data on the data tracks of the disk (e.g., movies, games, application programs, music, etc.). Such modifications are intended to fall within the scope of the present invention.

Turning to FIGS. 2 a-d, partial cross-sectional views are provided of four exemplary types of secure DVD discs 200 a-d. These simplified cross-sectional views (corresponding to a side view of the secure disc 100, when quartered) depict the general location of a security tag 202 within the layers of exemplary secure disc structures. The security tag 202, by way of example, comprises a polypropylene or polyethylene/Mylar backing material imprinted with a metallic coil circuit. In an embodiment of the invention, the security tag 202 includes a capacitor device that is short-circuited during deactivation (at the checkout counter). Suitable manufacturers of such tags are All-Tag Security S.A. Z.A.E. of Belgium and Checkpoint Systems, Inc. of Thoroughfare, N.J.

In an exemplary embodiment of the present invention (the invention is potentially incorporated into any appropriate optical information disc type), the security tag 202 is embedded within any of a variety of DVDs conforming to the following dimensions. By way of example, each substrate is approximately 0.6 to 0.5 mm. (but may be thinner to accommodate multiple readable layers on a side) in the portion of the disc where optically sensed information is located. A bonding layer 204, used to hold the two substrates (including their reflective/transmissive data layers) together, is approximately 0.1 mm (0.04-0.07 mm recommended). As shown in FIGS. 2 a and 2 b, the non-readable area of one or more of the substrates may be thinner to accommodate the thickness of the security tag 202. Furthermore, as shown in FIGS. 2 a and 2 b, the bonding layer 204 potentially extends nearly all the way to the center hole—and the bonding/adhesive material making up the bonding layer 204 potentially covers both the top and bottom of the security tag 202. Therefore the total thickness of the DVD structure, regardless of readable data layer format, is approximately 1.20 mm. (+0.30 mm/−0.06 mm). In yet other embodiments, such as BLUE RAY discs, the single substrate is approximately 1.19 mm. The disc, by way of example has an outer diameter of 120.00 mm (+/−0.30 mm), and the center hole has a diameter of 15.00 mm (+0.15 mm/−0.00 mm). The values in parentheses represent tolerances specified by the standard, ECMA-267 3^(rd) Edition, April 2001, for 120 mm DVD read-only discs. In other embodiments, the outer diameter of the disc is substantially less than 120 mm., and in yet other embodiments the substrates/media are non-circular (but balanced in relation to a rotational axis). The above-specified dimensions and tolerances are intended to be exemplary and differ in alternative embodiments of the invention.

In an embodiment of the invention, the security tag 202 is located/embedded within a space/layer of a secure disc referred to herein as the bonding/adhesive layer 204 having a thickness of approximately 0.10 mm. A suitable manufacturer of a bonding resin for the bonding/adhesive layer 204 is Nagase California Corp. of Sunnyvale, Calif. The bonding/adhesive layer 204 is sandwiched between first and second polycarbonate substrates 208 x and 210 x of a secure DVD disc. Suitable polycarbonate material is provided by Teijin Kasei America of Alpharetta, Ga. The tag 202 preferably includes glue on at least one side to aid its placement on the disc. However, the glue can be placed on both sides to ensure secure bonding of the tag 202 and substrates of the disc. If only on one side, then resin flows over the opposing side before the two substrates are bonded together to form the disc.

Yet another embodiment of a secure disc including a minimized metal layer is based upon an optical information disc structure referred to as a BLUE RAY disc. A BLUE RAY disc (read by means of a blue laser beam) comprises a single substrate (approximately 1.19 mm thick). Data tracks are formed on a first surface of the substrate. A very thin, minimized, metal layer is deposited upon first surface of the substrate to form the optically readable surface. The minimized metal layer, in the instance of a BLUE RAY disc, is on the order of 40 nanometers or less—such that the metal layer does not effectively prevent reading the security tag by sensor panels in a retail establishment (e.g., as specified by a manufacturing standard). Thereafter, a thin lacquer coating (e.g., approximately 0.01 mm thick) is applied to the sputtered minimized metal layer. The data tracks are read through the relatively thin lacquer coating rather than the relatively thick substrate. In this particular arrangement, the tag 202 is placed within a molding cavity prior to injecting polycarbonate that forms the single substrate of the BLUE RAY disc. The polycarbonate flows over the tag and embeds/encapsulates the tag within the relatively thick substrate. In yet other embodiments, the substrate of a BLUE RAY disc is formed from two separate substrates that are thereafter bonded together to facilitate sandwiching the security tag 202 within the layers of the disc formed by the two separate substrates.

As demonstrated in the various embodiments of the secure disc depicted in FIGS. 2 a-c, the substrates are either “blank” or alternatively carry one or more metalized/reflective layers depending upon the disc capacity. It is noted that in illustrative embodiments of the invention at least one of the substrates 208 x and 210 x is potentially “thinner” near the center hole. This accommodates a portion of the security tag 202's thickness (approximately 0.02 mm) that exceeds the thickness of the bonding/adhesive layer 204 x. In embodiments of the invention, the two substrates are separately processed, and at a point just prior to bonding the two substrates 208 x and 210 x together, the security tag 202 is placed upon one of the two substrates. Thereafter, the two substrates are bonded together using any appropriate bonding/adhesive material which forms the bonding/adhesive layer 204 x. It is noted that the views depicted in FIGS. 2 a-c are not to scale, but are intended to show the general layers of various embodiments of a secure disc embodying the present invention.

FIG. 2 a depicts a schematic cross-sectional view of a secure disc 200 a referred to as a DVD-5 along with suggested/exemplary dimensions—that may vary in accordance with various embodiments of the invention. The DVD layers/format depicted in FIG. 2 a is used for DVD's that carry a variety of encoded data including, by way of example, movies and game console-based video game software. The disc 200 a generally depicts layered structures specified for a single-sided, single readable layer DVD-5 disc. In the illustrative example the DVD-5 disc 200 a includes a single reflective layer 206 a (approximately 30 nm thick) of aluminum. The thickness varies in accordance with various embodiments of the invention. A range of 29-33 nm thickness for the reflective layer 206 a provides acceptable results and balances the need to the shielding effect of the reflective layer and the need to provide a reliably reflective surface.

The security tag 202 (up to, for example, approximately 0.3 mm. thick including possibly backing and/or application glue layers) is sandwiched, along with a bonding/adhesive layer 204 a (approximately 0.07 mm.), between a blank (dummy) substrate 208 a (approximately 0.6 mm.) and a non-blank substrate 210 a (approximately 0.5 mm.) upon which the single reflective layer 206 a is deposited. It is specifically noted that the above layer thicknesses are provided for illustrative purposes and should not be construed as limiting the present invention. For example, modifications to the tag 202 thickness potentially influence the thickness of the substrate and bonding resin layers. The reflective layer 206 a is, by way of example, aluminum. In embodiments of the invention the blank substrate 208 a optionally includes printed artwork on its outer non-readable surface 212. Finally, it is noted that in the illustrative embodiments, the substrate 210 a thins beginning at point 213 of a non-readable portion adjacent to a center hole 215. The width difference in substrate 210 a (e.g., approximately 0.01 to 0.02 mm.) accommodates a difference in the thickness of the security tag 202 and the bonding/adhesive layer 204. While not specifically depicted in FIG. 2 a, the tag 202 is bonded to one, or both, of the substrates 208 a and 210 a with an adhesive (approximately 5 microns thick).

FIG. 2 b depicts a schematic cross-sectional view of a secure disc 200 b that incorporates the layered structures specified for a single-sided, dual readable layer DVD-9 disc. In the illustrative example the DVD-9 disc 200 b includes a reflective layer 206 b (e.g., approximately 30 nm) sputtered on a stamped substrate 208 b, and a semi-transmissive layer 207 b (approximately 10 nm), of gold, silver, silver alloy or silicon, that is sputtered on a stamped substrate 210 b. An exemplary range for the thickness of the semi-transmissive layer 207 b is 8-12 nm. Thus, in embodiments of the invention the reflective layer 206 b is substantially reduced (“minimized”) to reduce the shielding effect of the metal layers on the signal transmitted by the tag 202 when energized. The security tag 202 occupies a layer of the DVD structure that is also occupied by a transparent bonding/adhesive layer 204 b between the stamped substrate 208 b which carries the reflective layer 206 b, and the semi-transmissive layer 207 b sputtered upon the substrate 210 b. Methods for fabrication of the two readable layers on a single side of a DVD-9 disc are known to those skilled in the art. In exemplary embodiments of the invention, the reflective layer(s) are aluminum and the transmissive layer(s) are gold, silver, silver alloy, or silicon. The layer thicknesses for the DVD-9 structure are generally the same as the ones described above for FIG. 2 a.

FIG. 2 c depicts a schematic cross-sectional view of a secure disc 200 c that incorporates the layered structures specified for a double-sided, dual readable layer DVD-18 disc. In the illustrative example the DVD-18 disc 200 c includes on a first readable side: a reflective layer 206 c, a transparent bonding layer 209 c and a semi-transmissive layer 207 c fabricated on/attached to substrate 210 c. The second readable side includes: a reflective layer 216 c, a transparent bonding layer 219 c and a semi-transmissive layer 217 c fabricated on/attached to substrate 208 c. While not specifically depicted in FIG. 2 c, protective layers (see FIG. 6 a and FIG. 6 b) are spin coated on their respective halves of the disc 200 c to protect the reflective metal layers. Thereafter, the secure tag 202 is placed upon one of the two halves of the DVD-18 corresponding to substrates 208 c and 210 c. Finally, the two halves are brought together to form a layered structure wherein the security tag 202 occupies a layer of the DVD structure that is also occupied by the bonding/adhesive layer 204 c between the protective layers. In yet another embodiment, the security tag 202 is placed between substrate halves of a dual-readable side DVD-14 structure. It is noted that, in the illustrative embodiment, the thickness of the metal and bonding layers are sufficiently thick in the DVD-18 structure such that a change in substrate thickness is not needed at point 213. In other embodiments the thickness of one or more of the two substrates is thinned at a portion where the tag is placed to accommodate the tag thickness.

Turning briefly to FIGS. 3 a-d, a set of exemplary configurations/geometries for the security tag are provided. As explained previously above, the security tag fits, by way of example, within the clamping area of a DVD or other optically readable data storage disc. The coils of the security tag can take any of a number of shapes and sizes—subject to the space limitations imposed by the disc geometry. FIGS. 3 a, 3 b and 3 c schematically depict embodiments of miniature coil configurations. In these embodiments signal strength is enhanced by creating multiple replicated coil pairs and distributing the coils around the perimeter of a ring substrate for the security tag 202. FIG. 3 d, on the other hand, derives signal strength through the use of large ring-shaped coils that conform to the ring-shape of the security tag 202's substrate. Alternative embodiments of the invention utilize other shapes/coil layouts.

Having described exemplary structural features of exemplary DVD structures embodying the present invention, attention is directed to the methods for fabricating such structures. Referring to the sequence of FIGS. 4 a-b, 5 a-b and 6 a-b, the process for manufacturing DVD-14 and DVD-18 disc structures is summarized by way of identifying the layers at each of three primary stages. It is noted initially that a DVD-14 is two-readable-side DVD having a DVD-9 readable side and a DVD-5 readable side bonded together. A DVD-18 has two DVD-9 readable sides bonded together. The overall thickness of the DVD discs conforms to the 1.20 mm thickness specification.

Generally, in order to maintain the overall thickness specification of 1.20 mm. for a DVD, substrates used to fabricate the multiple readable layers are stripped and discarded so that the combined thickness is still 1.20 mm. To facilitate such stripping, an acrylic blank (that will release the aluminum without damaging the reflective layer) is used as the substrate for the reflective layer. The process starts with the manufacturing of a DVD 9 and a DVD 5 combination for DVD-14 or two DVD-9's for DVD-18. The information for the three readable layers for DVD-14 originates from three different stampers. Four stampers are used to produce the readable layers for DVD-18.

FIGS. 4 a and 4 b illustratively depict the initial molding/bonding processes. When a DVD-14 is manufactured, the half disc for the DVD-5 portion is molded. However, as shown in FIG. 4 b, it is not necessary to bond a blank substrate to the DVD-5 disc because it will eventually be bonded to the DVD-9 substrate. The DVD-9 substrates are manufactured in the nearly same way as standard DVD-9's. However, the DVD-9 portion of the sandwich includes an acrylic layer for layer 1 instead of the standard polycarbonate used for DVD-9. Acrylic is used for the layer 1 substrate because it adheres poorly to aluminum.

The acrylic layer, which has the information molded into its surface from a stamper, can be pealed off the substrate during a stripping process, leaving the information embossed in the cured bonding lacquer layer with an aluminum surface. In principle, the acrylic substrate acts like a stamper as it is used to transfer the image of the pits into the cured bonding resin. The stripping process results in the layered structures described in FIGS. 5 a and 5 b. After the two DVD-9's in the case of DVD-18 are made or a DVD-9 and DVD-5 are made in the case of DVD 14, the DVD 9 portions go to the stripping process. The stripping process peals the acrylic substrates off the surface.

After stripping, the two disc halves are bonded together to yield a two-sided disc with four layers (two per side) for DVD-18 or a two-sided disc with three layers—two on one side and a single layer on the other—for DVD-14. A first step before the second bonding process comprises spin coating the exposed aluminum sides of the previously stripped disc halves with a CD-type UV protective coating. After the halves are protective coated (two DVD-9 disc halves for DVD-18 or one DVD-5 half and one DVD-9 half for DVD-14) the disc halves are bonded together. In accordance with an exemplary embodiment of the invention, the security tag 202 is applied to one of the two disc halves either during molding of a substrate or alternatively after sputtering and prior to re-bonding. In a particular illustrative embodiment, while an indexing carousel transfers a disc half containing the reflective metal layer to the final bonding stage, rotation of the table is temporarily paused and an applicator attaches (e.g., dispenses and tamps in place) the security tag 202 to the disc half prior to the application of the bonding resin and the final combination of the disc by a consolidator machine. After the bonding step a clamping mechanism ensures that the two substrates are securely attached to the tag and that the security tag 202 does not compromise the structural integrity of the secure disc 200.

Once the disc halves are bonded together the security tag 202 cannot be removed, yet the disc maintains all of the structural integrity of non-secure discs that do not include the security tag 202 embedded between the two substrates. FIGS. 6 a and 6 b provide the final configuration for the DVD-18 and DVD-14 formats. The security tag 202 is contained in the second bonding layer.

Turning to FIG. 7 a portion of a DVD assembly line is depicted. The illustrative set of machines manufactures either DVD-5 or DVD-9 (depending upon whether both sides are stamped/sputtered). Each substrate is initially produced by a molding/stamping sub-assembly 700 or 702 by Meiki Molding of Nagoya, Japan. Alternative providers of equipment include Singulus, of Kahl am Main, Germany. Transfer arms 704 and 706 transfer the substrates to sputtering machines 708 and 710 made by UNAXIS of Luxembourg, if the substrate is a non-blank substrate. The sputtered or blank substrate is transferred by the transfer arms 704 and 706 to an indexing carousel 712. In an embodiment of the invention, while the substrate is laying, inside face up, on the indexing carousel 712 at position 714 (before applying a bonding resin and consolidating the two halves to form a single DVD, a tag applicator applies the security tag 202 to one of the two halves. Thereafter, the DVD halves are transferred by a transfer arm 716 to a consolidating assembly 718. A flipper 720 flips one of the two disc halves in preparation for consolidation while an applicator 722 applies bonding resin to the other half. Thereafter, a consolidator 724 mates the two halves of the disc to render a DVD-5 or DVD-9 disc. Thereafter, a spinner spins excess bonding resin from the consolidated disc assembly and the resin is cured through exposure to a UV light source. Inspection and printing stages complete the exemplary DVD assembly processes. The robotic transfer arms, indexing carousel 712 and components of the consolidating assembly 718 are provided, for example, by Origin of Tokyo, Japan.

Turning to FIGS. 8 a and 8 b, a set of schematic flow diagrams illustratively depict the primary stages for creating replicated DVD-5 and DVD-9 discs, respectively. These figures schematically depict two alternative sequences of operations performed by the manufacturing line depicted in FIG. 7. With reference to FIG. 8 a, a stamper line generates an embossed substrate at stage 800. Thereafter, the reflective (aluminum) coating is applied (sputtered) at stage 802 to render the data bearing half of the disc. It is during this stage that the mirror/ID band is also applied by sputtering. However, appropriate masking is utilized to introduce a discontinuity between the metal of the digital data portion of the disk and the metal for the mirror/ID band of the disk. An exemplary pattern of metalization is provided on FIG. 9 b (described below). At stage 804, while the disc half containing the reflective metal layer is being transferred to a bonding stage 806, wherein the data half is mated with a blank substrate provided by molding stage 807, the security tag 202 is applied to the “reflective” half. It is noted that in alternative embodiments of the invention, the security tag 202 is initially applied to the blank half after molding stage 807. It is further noted that in yet other, less preferred, embodiments, the tag 202 is embedded within either of the two substrate halves during either of the two injection molding stages 800 and 807. After the bonding stage 806, described in greater detail above with reference to FIG. 7, the disc is inspected at stage 808. Thereafter, printing is placed upon the blank side of the DVD during stage 810.

With reference to FIG. 8 b, a stamper line generates an embossed substrate at stage 820. Thereafter, the reflective (aluminum) coating is applied (sputtered) at stage 822 to render one data bearing half of the DVD-9 disc—including the sputtered mirror/ID band as well. At stage 824, while the disc half containing the reflective metal layer is being transferred to a bonding stage 826, wherein the data half containing the reflective metal (Al) layer is mated with a second data half containing a semi-transmissive metal (Ag or Au) layer provided by stamper stage 827 and semi-transmissive layer stage 829, the security tag 202 is applied to the “reflective” half. It is noted that in alternative embodiments of the invention, the security tag 202 is initially applied to the “semi-transmissive” half after the semi-transmissive layer stage 829. However, for timing purposes, in an embodiment of the invention wherein one of the two sputtering processes takes longer than the other (e.g., the semi-transmissive layer takes longer to produce than the reflective layer), the security tag is applied to the half that takes less time to coat with a metal layer. It is further noted that in yet other, less preferred, embodiments, the tag 202 is embedded within either of the two substrate halves during either of the two injection molding stages 820 and 827. After the bonding stage 826, described in greater detail above with reference to FIG. 7, the DVD-9 disc is inspected at stage 828. Thereafter, printing is placed upon the blank, non-readable side of the DVD-9 disc during stage 830.

Turning to FIGS. 9 a and 9 b, an exemplary plan view is provided of the layout for a metalization layer on a secure information disc incorporating the present invention. In particular, FIG. 9 b depicts discontinuities introduced on a metalization pattern on a disc to facilitate improving the ability to sense the security tag 102 signal when passing through a security gate. FIG. 9 a depicts a prior art metalization pattern for an optical data disc wherein a single, continuous layer of metal is provided for both the data tracks (beyond the 45 mm circular region) and the mirror/ID band (within the 45 mm circular region). In contrast, a metalization layer of a disc embodying the present invention, depicted in FIG. 9 b, contains a first discontinuity 900, in the form of a ring having an inner diameter of 44.0 mm and an outer diameter of 45.0 mm. The first discontinuity 900 provides conductive separation between the metal making up a digital data portion 902 of the disc and metal making up a mirror/ID band portion 904 of the disc. In the exemplary embodiment, the discontinuity is about 0.5 mm. However, other widths can be utilized in accordance with alternative embodiments of the invention.

In further distinction from the prior art (FIG. 9 a), the metalization pattern within the mirror/ID band portion 904 of the disc includes a second discontinuity 906. The discontinuity 906, having a width (by way of example and not limitation) of 0.1 to 1.0 mm, creates an opening in the ring metalization pattern within the mirror/ID band portion 904 of the disc. The width of the discontinuity 906 varies in accordance with alternative embodiments of the invention. The second discontinuity 906 in the metalization pattern of the disc, like the first discontinuity 900, improves the ability of signal sensors to pick up a signal transmitted by the (energized) security tag 102.

In view of the many possible embodiments to which the principles of this invention may be applied, it should be recognized that the embodiments described herein with respect to the drawing figures are meant to be illustrative only and should not be taken as limiting the scope of invention. Furthermore, the illustrative steps may be modified, supplemented and/or reordered (at least in part) without deviating from the invention. Therefore, the invention as described herein contemplates all such embodiments as may come within the scope of the following claims and equivalents thereof. 

1. A secure optical data storage disc comprising: a first substrate; a reflective metalization layer disposed upon the first substrate, wherein the reflective metallization layer is approximately 40 nanometers in thickness or less; and an annular ring volume comprising a security tag.
 2. The secure optical data storage disc of claim 1 wherein the reflective metallization layer is less than 33 nanometers and greater than 29 nanometers.
 3. The secure optical data storage disc of claim 1 wherein the disc structure conforms to the structural specifications of a BLUE RAY disc.
 4. The secure optical disc of claim 1 wherein the optical disc has only a single substrate, and wherein the security tag is encapsulated within the single substrate.
 5. The secure optical data storage disc of claim 1 wherein the reflective metalization layer comprises a first discontinuity, thereby forming conductive isolation between a first portion corresponding to a digital data tracks region and a second portion corresponding to a non-digital data tracks region of the disc.
 6. The secure disc of claim 5 wherein the metalization layer comprises a second discontinuity that creates an opening in a substantially complete ring corresponding to the second portion of the metalization layer.
 7. A method for manufacturing a secure optical data storage disc comprising a first substrate and a an annular ring volume that is not occupied by data tracks, the method comprising: forming the first substrate; depositing a reflective metalization layer upon the first substrate, wherein the reflective metallization layer is approximately 40 nanometers in thickness or less; and securing a security tag to the first substrate within the annular ring volume.
 8. The method of claim 7 wherein the reflective metallization layer is less than 33 nanometers and greater than 29 nanometers.
 9. The method of claim 7 the data storage disc structure conforms to the structural specifications of a BLUE RAY disc.
 10. The method of claim 7 wherein the optical disc has only a single substrate, and wherein the securing step comprises encapsulating the security tag within the single substrate.
 11. The method of claim 7 wherein the reflective metalization layer comprises a first discontinuity, thereby forming conductive isolation between a first portion corresponding to a digital data tracks region and a second portion corresponding to a non-digital data tracks region of the disc.
 12. The method of claim 11 wherein the metalization layer comprises a second discontinuity that creates an opening in a substantially complete ring corresponding to the second portion of the metalization layer.
 13. The secure optical data storage disc of claim 1 wherein the reflective metallization layer is approximately 30 nanometers in thickness or less.
 14. The method of claim 7 wherein the reflective metallization layer is approximately 30 nanometers in thickness or less. 